Methods of Estimation

CAS Task Force on Fair Value Liabilities

White Paper on Fair Valuing Property/Casualty Insurance Liabilities

Section K - Appendices

Table of Contents

Appendix 1: CAPM Method

Appendix 2: IRR Method

Appendix 3: Single Period RAD model

Appendix 4: Using Underwriting Data

Appendix 5: The Tax Effect

Appendix 6: Using Aggregate Probability Distributions

Appendix 7: Direct Estimation of Market Values

Appendix 8: Distribution Transform Method

Appendix 9: Credit Risk

The Time Horizon Problem

Implied Option Value

Dynamic Financial Analysis

Rating Agency

Appendix 10: References

Appendix 1: CAPM Method

This appendix presents an example of computing a risk-adjusted discount rate using CAPM.

In its simplest form, the approach used in Massachusetts assumes that the equity beta for insurance companies is a weighted average of an asset beta and an underwriting beta. The underwriting beta can therefore be backed into from the equity beta and the asset beta.

here

e is the equity beta for insurance companies, or alternatively for an individual insurer

Ais the beta for insurance company assets

uis the beta for insurance company underwriting profits

k is the funds generating coefficient, and represents the lag between the receipt of premium and the average payout of losses in a given line

s is a leverage ratio

Since

or the equity beta is the covariance between the company’s stock return and the overall market return divided by the variance of the overall market return. It can be measured by regressing historical P&C insurance company stock returns on a return index such as the S&P 500 Index. Similarly, Acan be measured by evaluating the mix of investments in insurance company portfolios. The beta for each asset category, such as corporate bonds, stocks, real estate is determined. The overall asset beta is a weighted average of the betas of the individual assets, where the weights are the market values of the assets.

Example:

Assume detailed research using computerized tapes of security returns such as those available from CRISP concluded that e for the insurance industry is 1.0 and Afor the insurance industry is 0.15. By examining company premium and loss cash flow patterns, it has been determined that k is 2. The leverage ratio s is assumed to equal 2. The underwriting Beta is

orU = .5*(1. – (2*2+1).15) = .125

Once Uhas been determined overall for the P&C industry, an approach to deriving the beta for a particular line is to assume that the only factor affecting the covariance of a given line’s losses with the market is the duration of its liabilities:

So if the average duration in a given line is 2, its beta is -2*.125= -.25

In order to derive the risk-adjusted rate, the risk free rate and the market risk premium are needed. Assume the current risk free rate is 6% and the market risk premium (i.e., the excess of the market return over the risk free return) is 9%. Then the risk-adjusted rate is:

or rL = .06 - .25 * (.09) = .06 - .0225 =.0375

An alternative approach to computing the underwriting beta is to regress accounting underwriting returns in a line of business on stock market returns. The method suffers from the weakness that the reported underwriting returns often contain values for the liabilities that have been smoothed over the underwriting cycle, thus depressing their variability.

Appendix 2: IRR Method

All balance sheet values are at fair value. Thus, the liability value at each evaluation date must be calculated using a risk-adjusted interest rate. Since we are trying to find this value, it is an input that is iterated until the IRR equals the desired ROE. (This is easily done using the “Goal Seek” function in an Excel spreadsheet.)

The present value of the income taxes is a liability under a true economic valuation method. However, in the FASB and IASC proposals, it is not included.[1] The basis for this calculation is found in Butsic (Butsic, 2000). To a close approximation, the PV of income taxes equals the present value of the tax on investment income from capital, divided by 1 minus the tax rate. The PV is taken at an after-tax risk-free rate.

Exhibit A2 shows an example of the risk adjustment calculation, using the IRR method, for a liability whose payments extend for three periods.

Notes to Exhibit A2

Rows (Note that “R1” denotes Row 1, “R2” denotes Row 2, etc.):

1. Rate for portfolio of U. S. Treasury securities having same expected cash flows as the losses.

2. Expected return for the insurer’s investment portfolio. Note that the yield on a bond is not an expected return. The yield must by adjusted to eliminate expected default. Municipal bond yields are adjusted to reflect the implied return as if they were fully taxable.

3. Statutory income tax rate on taxable income.

4. Estimates can be obtained from Value Line, Yahoo Finance or other services.

5. Estimates are commonly available in rate filings (e.g., Massachusetts).

6. All-lines value an be estimated by adjusting historical industry reserve values to present value and adding back the after-tax discount to GAAP equity. See Butsic (1999) for an example. For individual lines, a capital allocation method can be used, such as Myers and Read (1999).

7. An arbitrary round number used to illustrate the method.

10. R1 + (R4 x R5).

11. R1 – R16.

12. (1 – R3) x R1

13. R25 + R26 (at time 0).

16. This value is iterated until the IRR (Row 45) equals R10.

21. R22 (Prior Year) + R37 + R38 + R39.

22. R21 + R43.

25. Present value of negative R38 using interest rate R11.

26. Present value of R41 using interest rate R12. Result is divided by (1 – R3).

27. (R6, capital/reserve) x R25.

28. R27 + R43.

31. Time 0: R37 – R25. Time 1 to 3: – R11 x R25 (Prior Year).

32. (R22, Prior Year) x R2.

33. R31 + R32.

34. (R28, Prior Year) x R1.

37. R13.

38. – R7 x payment pattern in Rows 4 though 7.

39. – R3 x R33.

41. R3 x R34.

43. R28 – R27

45. Internal rate of return on Row 43 cash flows.

Appendix 3: Single Period RAD model

All balance sheet values are at fair value.

The discussion of the income tax liability is the same as in Appendix 2.

Here, there is no iteration needed, since the risk adjustment is derived directly from the equations relating the variables to each other. Butsic (2000) derives this result.

The formula is

,

where the variables are:

zrisk adjustment to the risk-free rate

ccapital as a ratio to the fair value of the liability

Rrequired rate of return on capital (ROE)

expected return on assets (includes bond yields net of expected default)

risk-free rate

tincome tax rate

Although the risk adjustment can be calculated directly from the above formula, we have provided Exhibit A3, which shows that the risk adjustment in fact produces the required ROE and internal rate of return. The format of Exhibit A3 is similar to that of Exhibit A2. However, only a single time period is needed.

Note that exhibits A2 and A3 give slightly different results for the risk adjustment. This is because capital is needed for both asset and liability risk. In a multiple period model, the relationship between the assets and loss reserve fair value is not strictly proportional. This creates a small discrepancy.

Notes to Exhibit A3

Rows (Note that “R1” denotes Row 1, “R2” denotes Row 2, etc.):

1. Rate for portfolio of U. S. Treasury securities having same expected cash flows as the losses.

2. Expected return for the insurer’s investment portfolio. Note that the yield on a bond is not an expected return. The yield must by adjusted to eliminate expected default. Municipal bond yields are adjusted to reflect the implied return as if they were fully taxable.

3. Statutory income tax rate on taxable income.

4. Estimates can be obtained from Value Line, Yahoo Finance or other services.

5. Estimates are commonly available in rate filings (e.g., Massachusetts).

6. All-lines value an be estimated by adjusting historical industry reserve values to present value and adding back the after-tax discount to GAAP equity. See Butsic (1999) for an example. For individual lines, a capital allocation method can be used, such as Myers and Read (1999).

7. An arbitrary round number used to illustrate the method.

10. R1 + (R4 x R5).

11. R1 – R15

12. (1 – R3) x R1

14. R24 + R25 (at time 0).

15. R6 x (R10 – R1) / (1 – R3) – (R2 – R1) x [1 + R6 x (1 + R1) / (1+R12)].

20. R21 (Prior Year) + R36 + R37 + R38.

21. R20 + R42.

24. Present value of R7 using interest rate R11.

25. Present value of R40 using interest rate R12. Result is divided by (1 – R3).

26. Time 0: 0; Time 1: R20 – R24 – R25.

27. R6 x R24.

30. Time 0: R36 – R24. Time 1: – R11 x R24 (Prior Year).

31. (R21, Prior Year) x R2.

32. R30 + R31.

33. (R27, Prior Year) x R1.

36. R14.

37. Time 0: 0. Time 1: – R7.

38. – R3 x R32.

40. R3 x R33.

42. R27 – R26

44. (R26, Time 1) / (R27, Time 0) – 1.

46. Internal rate of return on Row 42 cash flows.

Appendix 4: Using Underwriting Data

This appendix describes Butsic’s procedure for computing risk adjusted discount rates. The following relationship is used for the computation.

Where:

C is the cash flow on a policy and can be thought of as the present value of the profits, both underwriting and investment income, on the policy,

P is the policy premium,

E is expenses and dividends on the policy,

L is the losses and adjustment expenses,

uis the average duration of the premium, or the average lag between the inception of the policy and the collection of premium,

w is the average duration of the expenses,

t is the average duration of the liabilities.

i is the risk free rate of return

iA is the risk adjusted rate of return

This formula says that the present value cash flow or present value profit on a group of policies is equal to the present value of the premium minus the present value of the components of expenses minus the present value of losses. Premiums and expenses are discounted at the risk free rate. Each item is discounted for a time period equal to its duration, or the time difference between inception of the policy or accident period and expiration of all cash flows associated with the item. Losses are discounted at the risk-adjusted rate. Underwriting data in ratio form, i.e., expense ratios, loss ratios, etc. can be plugged into the formula. When that is done, P enters the formula as 1, since the ratios are to premium.

In ratio form this formula would be:

c is the ratio of present value profit to premium

e is the expense ratio, including dividends to policyholder

l is the loss ratio

Using as a starting point the rate of return on surplus, where the surplus supporting a group of policies is assumed to be eVm, or the leverage ratio times the average discounted reserve, Butsic (Bustic, 1988) derived the following simplified expression for the risk adjustment:

,

where:

Z is the risk adjustment to the interest rate or the percentage amount to be subtracted from the risk free rate = e(R - i)

C and i are as defined above

Vm is the average discounted reserve for the period

Vm is generally taken as the average of the discounted unpaid liabilities at the beginning of the accident or policy period (typically 100% of the policy losses) and the discounted unpaid liabilities at the end of the period. In general, this would be equal to 100% plus the percentage of losses unpaid at the end of the period (one year if annual data is used) divided by 2. The discount rate is the risk-adjusted rate. If Vmis computed as a ratio to premium, then published loss ratios are discounted and used in the denominator.

To complete the calculation, the quantity c, or the ratio of discounted profit to premium should be multiplied by (1 + i) and divided by vm (Vm in ratio form). To derive initial estimates of the risk adjustment, it is necessary to start with a guess as to the value of the risk adjustment to the discount rate in order to obtain a value for discounted liabilities.

The following is an example of the computation of the risk adjustment using this method. It is necessary to start with a guess for the risk adjustment and then perform the calculation iteratively until it converges on a solution. This example is based on data in Butsic’s (1988) paper.

Parameter assumptions
Interest Rate Rf / 0.0972
Fraction of losses OS after 1 year / 0.591
Initial Risk Adjustment / 0.044
Variable / Nominal Value / Duration / Discounted Value
1 / Loss&LAE / 0.767 / 2.300 / 0.681
2 / Premium / 1.000 / 0.250 / 0.977
3 / UW Expense / 0.268 / 0.250 / 0.262
4 / Pol Dividends / 0.016 / 2.250 / 0.013
5 / Average Liabilities / 0.610 / 1.800 / 0.556
Calculation
6 / Premium-Expenses Discounted
(2) - (3) - (4) / 0.702
7 / Premiums-Expenses-Losses Disc / 0.021
(6)-(1)
8 / C*(1+I) / 0.024
(7)*(1+I)
9 / Z=C*(1+I)/Vm / 0.042
(8)/(5)

An additive risk load

An additive or dollar risk load can be computed from the same data. The formula for the computation of a risk load is:

Where rl is the additive risk load and i is the risk free interest rate.

An example is shown below:

Parameter assumptions
Interest Rate Rf / 0.0972
Variable / Nominal Value / Duration / Discounted Value
1 / Loss&LAE / 0.767 / 2.300 / 0.620
2 / Premium / 1.000 / 0.250 / 0.977
3 / UW Expense / 0.268 / 0.250 / 0.262
4 / Pol Dividends / 0.016 / 2.250 / 0.013
Calculation
5 / Premium-Expenses Discounted
(2) - (3) - (4) / 0.702
6 / C =Premiums-Expenses-Losses Disc / 0.083
(5)-(1)
7 / C/PV(Losses) / 0.133
(6)/(1)

Appendix 5: The Tax Effect

More recent work by Butsic (Butsic, 2000) has examined the effect of taxes on the risk adjusted discount rates and insurance premium. Butsic argued that, due to double taxation of corporate income, there is a tax effect from stockholder supplied funds. Stockholder funds are the equity supplied by the stockholder to support the policy. In the formulas above, stockholder supplied funds are denoted by E and taken to be the ratio of e to the present value of losses . For a one period policy an amount E is invested at the risk free rate i, an amount Ei of income is earned, but because it is taxed at the rate t, the after tax income is E i(1 - t). The reduced investment income on equity will be insufficient to supply the amount needed to achieve the target return. In order for the company to earn its target after tax return, the amount lost to taxes must be included in the premium. However, the underwriting profit on this amount will also be taxed. The amount that must be added to premium to compensate for this tax effect is:

This is the tax effect for a one period policy if the discount rate for taxes is the same as the discount rate for pricing the policy, i.e., the risk adjusted discount rate. Butsic shows that there is an additional tax effect under the current tax law, where losses are discounted at a higher rate than the risk adjusted rate. There is also a premium collection tax effect, due to lags between the writing and collecting of premium. This is because some premium is taxed before it is collected. Butsic developed an approximation for all of these effects taken together, as well as the multiperiod nature of cash flows into the following adjustment to the risk adjusted discount rate:

,where

iA’ is the tax and risk adjusted rate,

e is a leverage ratio,

t is the tax rate,

rTis the pre tax return on equity.

This is the effective rate used to discount losses to derive economic premium. The tax effect acts like an addition to the pure risk adjustment. Since premiums as stated in aggregate industry data already reflect this tax effect, no adjustment is needed for the risk adjusted discount rate used for pricing. However, for discounting liabilities, it may be desirable to segregate the tax adjustment from the pure risk adjustment, since the tax effect really represents a separate tax liability. Using the formula above, as well as the formula for determining the pure risk adjustment to the discount rate the two effects could be segregated. One would need to have an estimate of the total pre tax return on equity.

Appendix 6: Using Aggregate Probability Distributions

This example uses the Collective Risk Model to compute a risk load. It represents only one of the many approaches based on aggregate probability distributions. This is in order to keep the illustration simple.

The approach is based on the following model for risk load:

• Risk Load =  SD[Loss] or Risk Load = Var[Loss],

Therefore, in order or compute a risk load, two quantities are needed:  and Var[Loss], since SD(Loss) = Var[Loss]1/2. The following algorithm from Meyers (Meyers, 1994) will be used to compute the variance of aggregate losses.

The Model:

1. Assume claim volume has an unconditional Poisson distribution.

2. Assume the Poisson parameter, n (the claim distribution mean), varies from risk to risk.

3. Select a random variable  from a distribution with mean 1 and variance c.

4. Select the claim count, K, at random from a Poisson distribution with mean n, where the random variableis multiplied by the random Poisson mean n.

The Variability of Insurer Losses

5. Select occurrence severities, Z1, Z2, .., ZK, at random from a distribution with mean  and variance 2.

1. The total loss is given by:

The expected occurrence count is n ( i.e. E[(n] = E[n] = n). n is used as a measure of exposure.

When there is no parameter uncertainty in the claim count distribution c = 0,

Var[x] = n (2 + 2),

and variance is a linear function of exposures.

When there is parameter uncertainty:

Var[x] = nu + n2v,

where

u = (2 + 2)

and

v = c2

nu is the process risk and n2v is the parameter risk.

For example, assume an insurer writes two lines of business. The expected claim volume for the first line is 10,000 and the expected claim volume for the second line is 20,000. The parameter c for the first line is 0.01 and for the second line is 0.005. Let the severity for line 1 be lognormal with a mean of $10,000 and volatility parameter (the standard deviation of the logs of losses) equal to 1.25 and the severity for line 2 be lognormal with severity of $20,000 and volatility equal to 2. Applying the formula above for the variance of aggregate losses, we find that the variance for line 1 is 1.05x 1014 and the variance of line two is 1.24 x 1015 and the sum of the variances for the two lines is 1.34 x 1015. The standard deviation is $36,627,257.

One approach to determining the multiplier  would be to select the multiplier ISO uses in its increased limits rate filings. In the increased limits rate filings,  is applied to the variance of losses and is on the order of 10-7.(Meyers, 1998)

In recent actuarial literature, the probability of ruin has been used to determine the multipliers of SD(loss) or Var(Loss). (Kreps 1998, Meyers 1998, Philbrick, 1994). The probability of ruin or expected policyholder deficit is used to compute the amount of surplus required to support the liabilities. To keep the illustration simple, we use the probability of ruin approach. However, the expected policyholder deficit or tail value at risk (which is similar to expected policyholder deficit) approaches better reflect the current literature on computing risk loads. Suppose the company wishes to be 99.9% sure that it has sufficient surplus to pay the liabilities, ignoring investment income, the company will require surplus of 3.1 times the standard deviation of losses, if one assumes that losses are normally distributed.[2] In order to complete the calculation, we need to know the company's required return on equity, re. This can be determined by examining historical return data for the P&C insurance industry. Then the required risk margin for one year is re x 3.1x 36,627,257. For instance, if re is 10% then the risk margin is 11,354,450 or about 2.0% of expected losses. In this example, the parameter lambda is equal to 3.1 re. The result computed above could be converted into a risk margin for discounted losses by applying the 2% to losses discounted at the risk free rate. This would require the assumption that the risks of investment income on the assets supporting the losses being less than expected is much less than the risk that losses will be greater than expected. When the assets supporting the liabilities are primarily invested in high quality bonds, this assumption is probably reasonable. (see D’Arcy et. al., 1997)